DE102004036994A1 - Digital high-frequency input area with small intermediate frequency with several modes and corresponding procedure - Google Patents

Abstract

A data communication technique is provided that can be applied to wireless LAN (wireless local area network) receivers. Data signals are received that are modulated according to one of at least two different modulation schemes. The input portion of the device has an analog and a digital portion, the digital input portion comprising first and second signal processing branches for processing received data signals modulated according to different modulation schemes. The first and the second signal processing branch have a topology with a small IF (intermediate frequency). Furthermore, a correspondingly integrated circuit chip and a method for processing received data signals are provided.

Description

Background of the invention

Field of the invention

The This invention relates generally to data communication devices, about wireless (wireless Short-range network receiver) and corresponding methods and in particular relates to high-frequency techniques in such facilities.

One wireless local area network is a flexible data communication system, that as an extension or as an alternative for a wired one LAN is set up. Taking advantage of radio frequency technology or Infrared technology send and receive wireless system data without wires, with the need for wired connections is minimized. Thus, WLAN system combine data network with user mobility.

nowadays In most WLAN systems, the technology is spread with Spectrum applied, d. H. a broadband radio frequency technique, the for use in reliable and secure communication systems. The technology with spread spectrum is considered a compromise between the Bandwidth efficiency and reliability, integrity and security designed. Often become two types of radiosystems with spread spectrum uses: frequency hopping systems and direct sequence systems.

Of the Standard, the wireless local area networks operating in the 2.4 GHz spectrum working, defining and regulating is the IEEE 802.11 standard. Around higher Data transfer rates to enable the standard extended to 802.11 b, the data rates of 5.5 and 11 Mbps in the 2.4 GHz spectrum possible. There are also additional ones Extensions for this.

Examples These extensions are the IEEE 802.11a, 802.11b, and 802.11g Default. The 802.11a specification concerns wireless ATM (asynchronous Transfer mode) systems and is mainly used in access nodes applied. The 802.11 a standard works at radio frequencies between 5 GHz and 6 GHz. Therein a modulation scheme is applied which as a "division and bundling in orthogonal frequencies "(OFDM) which allows data speeds up to 54 Mbps, but mainly Communication takes place at 6 Mbps, 12 Mbps or 24 Mbps. The 802.11b standard uses a modulation scheme known as complementary Encoding Keying (CCK), which allows for higher data rates and less of the error subject to multiple propagations. The 802.11 g standard may have data rates up to 54 Mbps in the 2.4 GHz frequency band using OFDM use. Since both the 802.11g and the 802.11b standard in the 2.4 GHz frequency band, these are completely interchangeable. The 802.11 g standard defines the CCK OFDM as an optional transmit mode, the the access modes of the 802.11a and 802.11b combined, and the transfer rates support up to 22 Mbps can.

WLAN receivers and other data communication devices typically have a system unit that processes radio frequency (RF) signals. This unit is generally referred to as input section. Basically, an input section includes radio frequency filters, intermediate frequency (IF) filters, multiplexers, demodulators, amplifiers, and other circuits that can provide functions such as amplification, filtering, conversion, and the like. According to 1 The input section usually contains an analog input section 100 , which is the analogue portion of a circuit preceding an analog-to-digital conversion. Thus, the analog input section leads 100 some analog signal processing in the unit 110 and some other functions as described above, and then outputs the analog signal to an analog-to-digital converter 130 out. The quantized, ie digitized, output signal of the analog / digital converter 130 then becomes a digital signal processor 140 fed.

How to get out 1 can recognize the analog input section 100 Furthermore, one unit of conventional data communication receivers 120 to convert the received (and preprocessed) analog signal to a lower frequency. Conventionally, RF carrier waves carrying data due to some modulation technique are converted from the high frequency carrier range to some other intermediate frequency by a process called mixing. After the mixing process, the baseband signal is recovered by some sort of demodulation scheme.

There are receiver architectures in which the unit 120 has a topology with ZF of zero and / or a small IF. This will now be more detailed with respect to the 2 and 3 described.

2 Figure 5 is a simplified diagram showing the implementation for a ZF of zero for integrated receivers. In the version with ZF equal to zero, the incoming signal, which is at radio frequency, by means of the mixer 200 converted directly into baseband (BB) or implemented. Such direct conversion architectures have lower filter requirements and can be integrated into standard silicon processing, making this technique potentially attractive for wireless applications. However, there may be problems with DC (DC) offset, IQ mismatch, and low-frequency noise.

3 shows the version with a small IF. As can be seen, the low IF architecture operates at an intermediate frequency that is close to the baseband (similar to the zero IF solution) and thus can be integrated in the same way as the zero IF circuits. However, there is a second buck converter 330 to convert the intermediate frequency signals to baseband. Small IF devices can avoid the problems of DC offset, IQ mismatch, and low-frequency noise, but require additional frame rejection. For this reason, a frame frequency rejection unit becomes 320 added in topology with small IF.

Consequently own the solutions with ZF equal to zero and low IF each have their own advantages and disadvantages. This is the reason why conventional communication devices exist, either the solution with the ZF equal to zero or the solution with the low ZF in the use analog input section. Furthermore, there is double band RF transmitter / receiver for WLAN systems, in which a technology with direct implementation for a WLAN mode and a Architecture with small ZF for another Wi-Fi mode can be used.

Overview of the invention

It an improved multi-mode data communication technique is provided, which can simplify manufacturing and improve efficiency.

According to one embodiment becomes a wireless receiver provided that can receive data signals according to a single one of at least two different modulation schemes are modulated. The wireless receiver comprises an input section with an analog input section unit and a digital input section unit. The digital input section unit comprises a first signal processing branch for processing received Data signals that are in accordance with a first of the at least two different modulation schemes are modulated, and includes a second signal processing branch for processing received data signals according to a second of the at least two different modulation schemes are modulated. The first and the second signal processing branch have a topology with a small IF.

According to one another embodiment an integrated circuit chip is provided which comprises a circuit for processing data signals, which according to a individual scheme of at least two different modulation schemes modulated are. This circuit comprises an input section circuit, the one input analog section circuit and a digital input section circuit having. The digital input section circuit comprises a first signal processing branch for processing received data signals, corresponding to a first of the at least two different ones Modulation schemes are modulated, and includes a second signal processing branch for processing received data signals according to a second of the at least two different modulation schemes are modulated. The first and the second signal processing branch have a topology with a small IF.

In a further embodiment discloses a method of processing received data signals in one Data communication device provided, wherein the data signals each with a scheme of at least two different modulation schemes are modulated. The data communication device comprises a An input section comprising an analog input section unit and a digital input section unit. The procedure comprising determining which of the at least two different Modulation schemes is applied to a received data signal. The The method further comprises carrying out a processing small IF of the received data signal in a first signal processing branch of digital input section unit when it is determined that a first of the at least two different modulation schemes is applied, or in a second signal processing branch of the digital input section unit when it is determined that a second of the at least two different modulation schemes is applied.

Short description the drawings

The accompanying drawings are included and form a part of the specification, to explain the principles of the invention. The drawings are not to be construed as limiting the invention to merely the illustrated and described examples of how the invention may be practiced and employed. Other features and advantages will be apparent from the following more particular description of the invention, as illustrated in the accompanying drawings, in which:

1 Fig. 10 is a block diagram showing the input portion of a conventional data communication receiver;

2 is a simplified representation showing the solution with ZF equal to zero;

3 is a simplified diagram showing the solution with small IF;

4 Fig. 10 is a block diagram showing components of a data communication device according to an embodiment;

5 is a block diagram in which the components of a digital input section of the in 4 shown device are shown; and

6 is a flowchart illustrating a process for operating in the 4 and 5 shown communication device according to one embodiment.

detailed Description of the invention

The illustrate embodiments The present invention will be explained with reference to the drawings, wherein same elements and structures by the same reference numerals Marked are.

As will be apparent from the more detailed description of the embodiments, is provided a multi-mode data communication receiver technique, wherein the digital input section has two or more branches for different ones Modulation schemes and wherein each branch is a topology owns with small ZF. As can be seen from the following description can, the application of two (or more) branches with smaller IF in the digital receiver input section the Simplify manufacturing and the efficiency of the receiver architecture improve.

It's on first 4 referenced; Here is shown a block diagram in which the analog input section 400 and the digital input section 440 the data communication device (such as a WLAN receiver) according to an embodiment is shown. The analog and the digital input section 400 . 440 are by means of an analog / digital converter 430 connected to the analog output signal of the analog input section 400 converted into digital signals. In one embodiment, the analog output signal of the analog input section 400 by means of an analog signal preprocessing unit 420 be preprocessed, which is part of the analog input section 400 can be. The quantized digital signal output from the analog-to-digital converter 430 may be a digital input section receiver unit 450 of the digital input section 440 for further processing. The resulting baseband signal then becomes the baseband receiver unit 460 the data communication device supplied.

It should be noted that the analog / digital converter 430 In the present embodiment, a part of the analog input section 400 can be. In a further embodiment, the analog / digital converter 430 in the digital input section 440 be arranged.

In the embodiments, the down conversion is from the radio frequency to the baseband in the digital input section 440 and in particular in the digital input section receiver unit 450 be executed.

How to get out 4 can see, includes the analog input section 400 Furthermore, a flow detection unit 410 which detects a feedforward signal in the incoming (and possibly preprocessed) signal and the analog-to-digital converter 430 activated when a forward signal is detected. For this purpose, the flow detection unit 410 of the analog input section 400 with the analog-to-digital converter 430 connected to provide an activation signal upon detection of a flow signal.

In an embodiment is the activation signal for set each individual forward and reset at the end of the useful signal. In a further embodiment becomes the activation signal when detecting a first forward set and at the end of the last payload in a sequence of Data packets that have a header field and a payload field, reset.

The flow detection unit 410 may also make a decision on the type of detected signal based on the characteristics of the pre-run. In particular, the flow detection unit 410 Modulation information and / or information with respect to a WLAN mode, such as the 802.11 b, a or g extract and this modulation information of the digital Input portion receiver unit 450 and the analog-to-digital converter 430 forward. As described in more detail below, the receiver unit 450 and the digital input section 440 and the analog-to-digital converter 430 exploit this modulation information for a correct operation of the branches with small IF.

In the present embodiment may be a modulation scheme of one that complies with the IEEE 802.11b Specification is compatible. In this mode, these signals can be Barkermodulated or CCK-modulated. Furthermore, IEEE 802.11a / g modes can be used using an OFDM modulation scheme.

It is now up 5 referenced; in the 4 shown components of the digital input section receiver unit 450 of the digital input section 440 are shown here in more detail. How out 5 has the digital input section receiver unit 450 two branches, each of which has a topology with a small IF. In further embodiments, more than two branches may be provided.

In the first branch off 5 will perform 802.11b standard compliant processing. This branch includes the down converter 560 , the all-pass filter 570 , the multiplexer 530 , the low-pass filter 540 and the sample rate converter 580 , In the second branch, OFDM signals compatible with the 802.11a, g are processed. This branch includes the high-pass filter 500 , the down-converter 510 , the signal processing unit 520 , the multiplexer 530 , the low-pass filter 540 and the sample rate converter 550 ,

Before the various components are explained in detail, it should be noted that the multiplexer 530 and the low-pass filter 540 Part of both branches are. By sharing this unity between the two branches, the development and manufacturing costs are significantly reduced. It should also be noted that other components may also be designed for sharing in other embodiments.

How to get out 5 can recognize, receive the common components 530 . 540 the modulation information signal from the forward detection unit 410 , This signal allows the units to reconfigure their special characteristics to properly meet the requirements of the appropriate modulation technique used in each mode.

Let us now explain an 802.11b branch; the quantized real output of the analog to digital converter 430 is first in the vicinity of the baseband by means of the down converter 560 reduced. In the 802.11b mode, the analog-to-digital converter becomes 430 controlled so that it has a quantization of 6 bits. In the present embodiment, the intermediate frequency is 7 MHz. The down converter 560 gives the downconverted complex signal to the allpass filter 570 out. The alllpass filter 570 performs all-pass filtering on the received IF complex signal for a phase non-linearity scheme formed in the analog input section 400 were caused. In the present embodiment, the all-pass filter is 570 an IIR filter (infinite impulse response filter).

Since the complex baseband signal can still have unwanted image frequency ranges, it is through the low-pass filter 540 directed to suppress these image frequency ranges. The low pass filter 540 has a cutoff frequency of about 6.7 MHz in the present embodiment when operating in 802.11b mode. The cut-off frequency of the present embodiment is chosen to be sufficiently low to remove the unwanted images but still slightly above the Nyquist frequency of 5.5 MHz to eliminate the effects of group delay distortion caused by the filter. to reduce.

In the present embodiment, the low-pass filter is 540 an elliptical IIR low pass filter.

The signal filtered for the image suppression is then the sample rate converter 580 which converts the sampling rate to 22 MHz and eventually passes the resulting signal to the baseband receiver portion compatible with the 802.11b standard.

In the 802.11b branch, the quantization is 6 bits before the down converter 560 and 10 bits after the down converter 560 with a (10,0) fixed-point interpretation. The latter relates to the range of the physical voltage value of the analogue / digital converter input. The expansion of the resolution from 6 to 10 bits by the down converter 560 may indicate a lack of power normalization in the digital input section 440 compensate.

Reference is now made to the 802.11 a / g branch; the quantized real output of analog-to-digital converter 430 is from the down converter 510 lowered to the vicinity of the baseband. The quantization of the analog-to-digital converter 430 in the 802.11a / g OFDM mode is 10 bits. The quantized real output of the analog to digital converter 430 First, a high pass filter 500 run through.

To the down converter 510 may be a signal processing in the unit 520 depending on the exact Wi-Fi mode. That is, the signal processing unit 520 can work differently in the 802.11a mode than in the 802.11g mode. In the present embodiment, the information regarding the mode of the signal processing unit 520 through the flow detection unit 410 of the analog input section 400 fed.

Unintended image frequency ranges are controlled by the low-pass filter 540 which in turn may be an elliptical IIR low pass filter. The low pass filter 540 has a cut-off frequency of about 9.2 MHz when operating in the 802.11a / d branch. The signal filtered by the frame rate areas, that of the low pass filter 540 is output, then the sampling rate converter 550 fed, which reduces the sampling rate by a factor of 2. The resulting signal is then supplied to the receiver portion of the data communications device compatible with the 802.11a / g.

The Quantization of the OFDM branch is 10 bits with one (10.1) Fixed point interpretation. Again, the just mentioned concerns the Range of the physical voltage value of the analogue / digital converter input.

As previously described those in the embodiments filters used may be elliptical IIR filters. In further embodiments can the filters are those without multipliers, as described in L. D. Milic, IEEE transactions via Signal Processing, Volume 47, No. 2, February 1999, pages 469 to 479, are described.

It is now up 6 referenced; Here, a flowchart showing the process for executing a small-IF multi-mode reception according to the embodiment is shown. In step 600 is a flow in the flow recording unit 410 of the analog input section 400 detected. The flow detection unit 410 then generates an activation signal and passes this to the analog / digital converter 430 to activate it (step 605 ). Furthermore, the Voriauferfassungseinheit analyzed 410 Properties of the preamble in step 610 to determine modulation information to transfer this information to the digital input section 440 and the analog-to-digital converter 430 supply. In step 615 Then, the received input signal is digitized with a degree of quantization of either 10 bits or 6 bits, depending on the mode indicated by the detected information.

When the received signal is modulated according to the IEEE 802.11b specification, the quantized signal is incremented 620 lowered, in step 625 filtered with the allpass, in step 630 filtered with the low pass and in step 635 subjected to a conversion of a sampling rate. In the 802.11a / g mode, initial filtering of the quantized signal can be achieved by a high pass in the steps 640 . 665 occur. The filtered signal will then be in the steps 645 or 670 reduced. Further, a signal processing in step 650 or in the step 675 depending on the WLAN mode. Eventually the signal will be in the steps 655 . 680 filtered through a low-pass filter and in the sampling rate by a factor of 2 in the steps 660 . 685 reduced. Finally, the generated baseband signal is passed to the baseband receiver portion of the device.

Even though the invention with respect to their physically structured accordingly embodiments the skilled person recognizes that various modifications, Variations and improvements of the present invention in light of above technical teaching and the study of the appended claims can be performed without of the spirit and intended scope of the invention departing. Furthermore, those areas that are assumed to be that the person skilled in the art is familiar with, not described herein, so as not to unnecessarily obscure the invention described herein. It It should therefore be noted that the invention is not limited by the specific illustrative embodiments is limited but only by the scope of the appended claims.

Claims (81)

A WLAN (wireless local area network) receiver adapted to receive data signals modulated according to an individual scheme of at least two different modulation schemes, the WLAN receiver having an input section (Fig. 400 . 430 . 440 ) with an analog input section unit ( 400 ) and a digital input section unit ( 440 . 450 ), wherein the digital input section unit comprises a first signal processing branch ( 560 . 570 . 530 . 540 . 580 ) for processing received data signals modulated according to a first of the at least two different modulation schemes, and a second signal processing branch ( 500 to 550 ) for processing received data signals modulated in accordance with a second of the at least two different modulation schemes, the first and second data processing branches each having a topology with a small IF (intermediate frequency). The wireless receiver according to claim 1, wherein the first signal processing branch and the second signal processing branch at least one unit in The topologies with small IF included, share the at least one unit is connected to a signal to receive which indicates which of the at least two different ones Modulation schemes currently applied to the received data signals is. The WLAN receiver according to claim 2, wherein the at least one unit comprises a low-pass filter unit ( 540 ) for frame rate rejection. The wireless receiver according to claim 3, wherein the low-pass filter unit at least one digital IIR (unlimited impulse response) filter includes. The wireless receiver according to claim 4, wherein the at least one IIR digital filter elliptical IIR filter is. The wireless receiver according to claim 3, wherein the low-pass filter unit has a cut-off frequency, which is selectively dependent is selected from the displayed modulation scheme. The WLAN receiver of claim 3, wherein the at least one unit further comprises a multiplexer unit (10). 530 ) for selectively connecting the low-pass filter unit to units of the first and second signal processing branches in response to the received signal indicative of the modulation scheme. The WLAN receiver according to claim 2, further comprising a pre-detection unit ( 410 ) configured to analyze forward information of received data signals and to generate the signal indicating which of the at least two different modulation schemes is currently applied to the received data signals. The wireless receiver according to claim 8, wherein the forward detection unit in the analog Input section unit is included. The WLAN receiver of claim 8, further comprising an analog-to-digital converter unit ( 430 ) connected to digitize an output signal of the analog input section unit to be supplied to the digital input section unit, the analog to digital conversion unit being configured to digitize the output signal with different degrees of quantization, the signal being indicative which of the at least two different modulation schemes is currently applied to the received data signals, the analog-to-digital converter unit ( 430 ) in order to control the degree of quantization depending thereon. The WLAN receiver of claim 8, further comprising an analog-to-digital converter unit ( 430 ) connected to digitize an output signal of the analog input section unit to be supplied to the digital input section unit, the preprocessing detection unit being configured to further generate an activation signal upon detection of a forward signal, the activation signal of the analog-to-digital conversion unit (10). 430 ) to activate this unit. The WLAN receiver according to claim 1, further comprising a forward detection unit ( 410 ) configured to analyze forward information of received data signals and to generate a signal indicating which of the at least two different modulation schemes is currently applied to the received data signals, the signal being fed to the digital input section unit to determine the operation of the first and the second signal processing branch. The wireless receiver according to claim 12, wherein the pre-lead detection unit in the analog input section unit is included. The wireless receiver according to claim 12, further comprising an analog-to-digital converter unit (430) which is connected, an output signal of the analogue To digitize the input section unit to supply to the digital input section unit is, wherein the flow detection unit is formed, an activation signal when detecting a forward, wherein the activation signal the analog / digital converter unit to activate the same. The wireless receiver according to claim 1, wherein the first of the at least two different modulation schemes a CCK (complementary Coding shift keying) modulation scheme. The wireless receiver according to claim 1, wherein the first of the at least two different modulation schemes a Bark modulation scheme. The wireless receiver according to claim 1, wherein the first signal processing branch is formed is to process received data signals accordingly IEEE 802.11b specification are modulated. The WLAN receiver according to claim 1, where at the second of the at least two different modulation schemes is an OFDM (division and bundling in orthogonal frequencies) modulation scheme. The wireless receiver according to claim 1, wherein the second signal processing branch is formed, received data signals to be processed according to the IEEE 802.11a and / or IEEE 802.11g specifications are modulated. The WLAN receiver of claim 1, wherein the first signal processing branch comprises a down-conversion unit ( 560 ) connected to receive a digitized real output signal of the analog input section unit and arranged to reduce the signal into a complex signal having an intermediate frequency near the baseband. The wireless receiver according to claim 20, wherein the digitized real output signal of the analog input section with a first degree of quantization is digitized and wherein the buck converter unit is formed is a degraded digital signal with a second degree to output quantization, the second degree of quantization different from the first degree of quantization. The wireless receiver according to claim 21, wherein said second degree of quantization is greater than that first degree of quantization is. The wireless receiver according to claim 21, wherein the second degree of quantization equals the degree of quantization of the digitized real output signal the analog input section unit that is the second signal processing branch before being reduced. The WLAN receiver according to claim 1, wherein the first signal processing branch is an all-pass filter unit ( 570 ) to account for an alignment of phase nonlinearities caused by the analog input section unit. The wireless receiver according to claim 24, wherein the all-pass filter unit comprises at least one digital IIR (unlimited impulse response) filter. The wireless receiver according to claim 25, wherein the at least one digital IIR filter an elliptical IIR filter. The WLAN receiver according to claim 1, wherein the first signal processing branch comprises a low-pass filter unit ( 540 ) for frame rate rejection. The wireless receiver according to claim 27, wherein the low-pass filter unit at least one digital IIR (unlimited impulse response) filter. The wireless receiver according to claim 28, wherein the at least one digital IIR filter an elliptical IIR filter. The wireless receiver according to claim 29, wherein the IIR elliptic filter has a cutoff frequency which is slightly above the Nyquist frequency is. The WLAN receiver of claim 1, wherein the first signal processing branch comprises a sample rate converter ( 580 ) adapted to reduce the sampling rate to a rate suitable for processing the signal at the baseband frequency. The WLAN receiver according to claim 1, wherein the second signal processing branch comprises a high-pass filter unit ( 500 ) connected to receive a digitized real output signal of the analog input section unit and to filter the signal as a high pass filter. The wireless receiver according to claim 32, wherein the high-pass filter unit at least one digital IIR (unlimited impulse response) filter includes. The WLAN receiver according to claim 1, wherein the second signal processing branch comprises a down conversion unit ( 510 ) connected to receive a digitized real-time representation of a received data signal and adapted to reduce the signal into a complex signal having an intermediate frequency in the vicinity of the baseband. The WLAN receiver according to claim 1, wherein the second signal processing branch comprises a signal processing unit ( 520 ) connected to receive a signal indicative of one of at least two different WLAN modes in which the second of the at least two different modulation schemes is applied, and configured to perform signal processing depending thereon. The WLAN receiver according to claim 1, wherein the second signal processing branch comprises a low-pass filter unit ( 540 ) for frame rejection. The wireless receiver according to claim 36, wherein the low-pass filter unit at least one digital IIR (unlimited impulse response) filter includes. The wireless receiver according to claim 37, wherein the at least one digital IIR filter an elliptical IIR filter. The wireless receiver according to claim 38, wherein the IIR elliptic filter has a cutoff frequency slightly above the Nyquist frequency is. The WLAN receiver of claim 1, wherein the second signal processing branch comprises a sample rate converter ( 550 ) adapted to reduce the sampling rate to a rate suitable for processing the signal at the baseband frequency. integrated circuit chip comprising a circuit for processing data signals modulated according to a single at least second different modulation scheme, the circuit comprising an input section circuit ( 400 . 430 . 440 ) with an analog input section circuit ( 400 ) and a digital input section circuit ( 440 . 450 ), wherein the digital input section circuit comprises a first signal processing branch ( 560 . 570 . 530 . 540 . 580 ) for processing received data signals modulated according to a first of the at least two different modulation schemes, and a second signal processing branch ( 500 to 550 ) for processing received data signals modulated in accordance with a second of the at least two different modulation schemes, the first and second signal processing branches having a topology with a small IF (intermediate frequency). A method of processing received data signals in a data communication device, wherein the data signals are modulated according to a respective at least two different modulation schemes, the data communication device having an input section with an analog input section unit and a digital input section unit, the method comprising: determining ( 600 . 610 ) which of the at least two different modulation schemes is applied to a received data signal; and execute ( 620 . 685 ) processing a small IF (intermediate frequency) of the received data signals in a first signal processing branch of the digital input section unit if it is determined that a first of the at least two different modulation schemes is applied or in a second signal processing branch of the digital input section unit if it is determined that a second of the at least two different modulation schemes is applied. The method of claim 42, wherein performing the Processing with small IF includes: Operate at least one Unit that is the first signal processing branch and the second Signal processing branch is shared; and Feeding to the at least one unit of a signal indicating which one the at least two different modulation schemes on the received data signal is applied. The method of claim 43, wherein operating the at least one unit comprises: executing ( 630 . 655 . 680 ) low-pass filtering for frame frequency rejection. The method of claim 44, wherein the low pass filtering includes: Operating at least one digital IIR (unlimited Impulse response) filter. The method of claim 45, wherein operating the at least one digital IIR filter comprises: Operate one elliptical IIR filters. The method of claim 44, wherein the low pass filtering Includes: Applying a cutoff frequency that is selectively dependent of the displayed modulation scheme. The method of claim 44, wherein operating the at least one unit further comprises: selective connection a low-pass filter unit for performing the low-pass filtering with units of the first and second signal processing branches dependent on the received signal indicating the modulation scheme. The method of claim 43, further comprising: analyzing ( 600 . 610 ) advance information of the received data signal; and generating the signal indicating which of the at least two different modulation schemes is applied to the received data signal. The method of claim 49, wherein the header information be analyzed by a lead-in detection unit, which in the analog input section unit is included. The method of claim 49, further comprising: digitizing ( 615 ) an output signal of the analog input section unit having one of a plurality of different quantization degrees; and supplying the digitized output signal to the digital input section unit, the degree of quantization depending on the Signal indicating that one of the at least two different modulation schemes is applied to the received data signal. The method of claim 49, further comprising: digitizing ( 615 ) an output signal of the analog input section unit; and supplying the digitized output signal to the digital input section unit, wherein the digitizing is activated by an activation signal ( 605 ), which is generated when detecting a pre-run. The method of claim 42, further comprising: analyzing ( 600 . 610 ) advance information of the received data signal; Generating a signal indicating which of the at least two different modulation schemes is applied to the received data signal; and supplying the signal to the digital input section unit to control the operation of the first and second signal processing branches. The method of claim 53, wherein the header information by a forward detection unit included in the analog input section unit is included, analyzed. The method of claim 53, further comprising: digitizing ( 615 ) an output signal of the analog input section unit; and supplying the digitized output signal to the digital input section unit wherein the digitizing is activated by means of an activation signal ( 605 ) that is generated when a lead is detected. The method of claim 42, wherein the first the at least two different modulation schemes is a CCK (Complementary Encoding Keystone) modulation scheme. The method of claim 42, wherein the first the at least two different modulation schemes a Barken modulation scheme is. The method of claim 42, wherein the first Signal processing branch processed received data signals, the according to the IEEE 802.11b specifications are modulated. The method of claim 42, wherein the second the at least two different modulation schemes an OFDM (division and bundling in orthogonal frequencies) modulation scheme is. The method of claim 42, wherein the second Processing branch received data signals processed in accordance with the IEEE 802.11a and / or IEEE 802.11g specification are modulated. The method of claim 42, further comprising: receiving a digitized real output signal of the analog input section unit in the first signal processing branch; and reduce ( 620 ) of the signal into a complex signal at an intermediate frequency near the baseband. The method of claim 61, wherein the digitized real output signal of the analog input section unit with a first degree of quantization is digitized, and wherein the Method further comprises: Issuing a degraded digital Signal with a second degree of quantization, wherein the second quantization degree differs from the first degree of quantization. The method of claim 62, wherein the second Quantization degree higher as the first degree of quantization. The method of claim 62, wherein the second Quantization degree equal to the degree of quantization of the digitized real output signal of the analog input section unit, the second signal processing branch before a reduction is forwarded. The method of claim 42, further comprising: performing ( 625 ) allpass filtering in the first signal processing branch to account for an alignment of phase nonlinearities caused by the analog input section unit. The method of claim 65, wherein the all-pass filtering includes: Operating at least one digital IIR (unlimited Impulse response) filter. The method of claim 66, wherein operating the at least one digital IIR filter comprises: Operate one elliptical IIR filters. The method of claim 42, further comprising: executing ( 630 ) low pass filtering in the first signal processing branch for frame frequency rejection. The method of claim 68, wherein the low pass filtering comprising: operating at least one digital IIR (unlimited impulse response) filter. The method of claim 69, wherein operating the at least one digital IIR filter comprises: Operate one elliptical IIR filters. The method of claim 70, wherein operating elliptical IIR filter includes: applying a cutoff frequency, which is slightly above the Nyquist frequency is. The method of claim 42, further comprising: transforming ( 635 ) the sampling rate in the first signal processing branch down to a rate suitable for processing the signal at the baseband frequency. The method of claim 42, further comprising: receiving a digitized real output signal of the analog input section unit; and execute ( 640 . 665 ) a high-pass filtering of the signal in the second signal processing branch. The method of claim 73, wherein the high pass filtering includes: Operating at least one digital IIR (unlimited Impulse response) filter. The method of claim 42, further comprising: receiving a digitized real representation of the received data signal in the second signal processing branch; and reduce ( 645 . 670 ) of the signal into a complex signal at an intermediate frequency near the baseband. The method of claim 42, further comprising: receiving in the second signal processing branch a signal identifying one of at least two different WLAN modes in which the second of the at least two different modulation schemes is applied; and performing signal processing ( 650 . 675 ) in the second signal processing branch in response to the signal. The method of claim 42, further comprising: executing ( 655 . 680 ) low-pass filtering in the second signal processing branch for the frame frequency rejection. The method of claim 77, wherein the low pass filtering includes: Operating at least one digital IRR (unlimited Impulse response) filter. The method of claim 78, wherein operating the at least one digital IIR filter comprises: Operate one elliptical IIR filters. The method of claim 79, wherein operating elliptical IIR filter includes: Applying a cutoff frequency, which is slightly above the Nyquist frequency is. The method of claim 42, further comprising: decreasing ( 660 . 685 ) the sampling rate in the second signal processing branch to a rate suitable for processing the signal at the baseband frequency.